IE50462B1 - Bacterial plasmid encoding human growth hormone - Google Patents
Bacterial plasmid encoding human growth hormoneInfo
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- IE50462B1 IE50462B1 IE2194/84A IE219480A IE50462B1 IE 50462 B1 IE50462 B1 IE 50462B1 IE 2194/84 A IE2194/84 A IE 2194/84A IE 219480 A IE219480 A IE 219480A IE 50462 B1 IE50462 B1 IE 50462B1
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- human growth
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- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
- C12N15/63—Introduction of foreign genetic material using vectors; Vectors; Use of hosts therefor; Regulation of expression
- C12N15/66—General methods for inserting a gene into a vector to form a recombinant vector using cleavage and ligation; Use of non-functional linkers or adaptors, e.g. linkers containing the sequence for a restriction endonuclease
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- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K14/00—Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof
- C07K14/435—Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof from animals; from humans
- C07K14/575—Hormones
- C07K14/61—Growth hormones [GH] (Somatotropin)
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- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
- C12N15/11—DNA or RNA fragments; Modified forms thereof; Non-coding nucleic acids having a biological activity
- C12N15/62—DNA sequences coding for fusion proteins
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- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
- C12N15/63—Introduction of foreign genetic material using vectors; Vectors; Use of hosts therefor; Regulation of expression
- C12N15/70—Vectors or expression systems specially adapted for E. coli
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- C12P21/00—Preparation of peptides or proteins
- C12P21/02—Preparation of peptides or proteins having a known sequence of two or more amino acids, e.g. glutathione
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- C07K2319/00—Fusion polypeptide
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- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K2319/00—Fusion polypeptide
- C07K2319/01—Fusion polypeptide containing a localisation/targetting motif
- C07K2319/02—Fusion polypeptide containing a localisation/targetting motif containing a signal sequence
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- C07K2319/50—Fusion polypeptide containing protease site
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- C07—ORGANIC CHEMISTRY
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- C07K2319/00—Fusion polypeptide
- C07K2319/70—Fusion polypeptide containing domain for protein-protein interaction
- C07K2319/74—Fusion polypeptide containing domain for protein-protein interaction containing a fusion for binding to a cell surface receptor
- C07K2319/75—Fusion polypeptide containing domain for protein-protein interaction containing a fusion for binding to a cell surface receptor containing a fusion for activation of a cell surface receptor, e.g. thrombopoeitin, NPY and other peptide hormones
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- C12R—INDEXING SCHEME ASSOCIATED WITH SUBCLASSES C12C - C12Q, RELATING TO MICROORGANISMS
- C12R2001/00—Microorganisms ; Processes using microorganisms
- C12R2001/01—Bacteria or Actinomycetales ; using bacteria or Actinomycetales
- C12R2001/185—Escherichia
- C12R2001/19—Escherichia coli
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S930/00—Peptide or protein sequence
- Y10S930/01—Peptide or protein sequence
- Y10S930/12—Growth hormone, growth factor other than t-cell or b-cell growth factor, and growth hormone releasing factor; related peptides
Abstract
Described are methods and means for the construction and microbial expression of quasi-synthetic genes arising from the combination of organic synthesis and enzymatic reverse transcription from messenger RNA sequences incomplete from the standpoint of the desired protein product. Preferred products of expression lack bio-inactivating leader sequences common in eukaryotic expression products but problematic with regard to microbial cleavage to yield bioactive material. Illustrative is a preferred embodiment in which a gene coding for human growth hormone (useful in, e.g., treatment of hypopituitary dwarfism) is constructed and expressed.
Description
Genetic Expression The DNA (deoxyribonucleic acid) of which genes are made comprises both protein-encoding or structural genes and control regions that mediate the expression of their information through provision of sites for RNA polymerase binding, information for ribosomal binding sites, etc. Encoded protein is expressed from its corresponding DNA by a multistep process within an organism by which: 1. The enzyme RNA polymerase is activitated in the control region (hereafter the promoter) and travels along the structural gene, transcribing its encoded information into messenger ribonucleic acid (mRNA) until transcription is ended at one or more stop codons. 2. The mRNA message is translated at the ribosomes into a protein for whose amino acid sequence the gene encodes, beginning at a translation start signal, most commonly ATG (which is translated f-methionine).
In accordance with the genetic code, DNA specifies each amino acid by a triplet or codon of three adjacent nucleotides individually chosen from adenosine, thymidine, cytidine and guanine or, as used herein, A,T,C, or G. These appear in the coding strand or coding seguence of double-stranded (duplex) DNA, whose remaining or complementary strand is formed of nucleotides (bases) which hydrogen bond to their complements in the coding strand, A complements T, and C complements G. These and other subjects relating to the background of the invention are discussed at length in Benjamin Lewin, Gene Expression 1, 2 (1974) and 3 (1977), John Wiley and Sons, N.Y.
DNA Cleavage and Ligation A variety of techniques are available for DNA recombination, according to which adjoining ends of separate DNA fragments are tailored in one way or another to facilitate ligation. The latter term refers to the formation of phosphodiester bonds between adjoining nucleotides, most often through the agency of the enzyme T4 DNA ligase. Thus, blunt ends may be directly ligated. Alternatively, fragments containing complementary single strands at their adjoining ends are advantaged by hydrogen bonding which positions the respective ends for subsequent ligation. Such single strands, referred to as cohesive termini, may be formed by the addition of nucleotides to blunt ends using terminal transferase, and sometimes simply by chewing back one strand of a blunt end with an enzyme such λ-exonuclease. Again, and most commonly, resort may be had to restriction endonucleases (hereafter, restriction enzymes), which cleave phosphodiester bonds in and around unique sequences of nucleotides of about 4-6 base pairs in length (restriction sites). Many restriction enzymes and their recognition sites are known. See, e.g., R. J, Roberts, CRC Critical Reviews in Biochemistry, 123 04β2 (Nov. 1976). Many make staggered cuts that generate short complementary single-stranded sequences at the ends of the duplex fragments. As complementary sequences, the protruding or cohesive ends can recombine by base pairing. When two different molecules are cleaved with this enzyme, crosswise pairing of the complementary single strands generates a new DNA molecule, which can be..gi..ven covalent integrity by using ligase to seal the single strand breaks that’ remain at the point of annealing. Restriction enzymes which leave coterminal or blunt ends on duplex DNA that has been cleaved permit recombination via, e.g., T4 ligase with other blunt-ended sequences.
Cloning Vehicles and Recombinant DNA For present purposes, a cloning vehicle is a nonchromosomal length of duplex DNA comprising an intact replicon such that the vehicle can be replicated when placed within a unicellular organism (microbe) by transformation. An organism so transformed is called a transformant. Presently, the cloning vehicles commonly in use are derived from viruses and bacteria and most commonly are loops of bacteria DNA called plasmids.
Advances in biochemistry in recent years have led to the construction of recombinant cloning vehicles in which, for example, plasmids are made to contain exogenous DNA. In particular instances the recombinant may include heterologous DNA, by which is meant DNA that codes for polypeptides ordinarily not produced by the organism susceptible to transformation by the recombinant vehicle. Thus, plasmids are cleaved with restriction enzymes to provide linear DNA having ligatable termini. These are bound to an exogenous gene having ligatable termini to provide a biologically functional moiety with an intact replicon and a phenotypical property useful in selecting transformants. The recombinant moiety is inserted into a microorganism by transformation and the transformant le isolated and cloned, with the object of obtaining large populations that include copies of the exogenous gene and, in particular cases, with the further object of expressing the protein for which the gene codes. The associated technology and its potential applications are reviewed in extenso in the Miles International Symposium Series 10: Recombinant Molecules: Impact on Science and Society, Beers and Bosseff, eds., Raven Press, N.Y. (1977).
Recombinant DNA Expression Aside from the use of cloning vehicles to increase the supply of genes by replication, there have been attempts, -some successful, to actually express proteins for which the genes code. In the first such instance a gene for the brain hormone somatostation under the influence of the lac promotor was expressed in S? toll bacteria. K. Itakura et al, Science 198, 1056 (1977). More recently, the A and B chains of human insulin were expressed in the same fashion and combined to form the hormone. D. V. Goeddel et al., Proc. Nat'l. Acad. Sci., USA 76 , 106 (1979). In each case the genes were constructed in their entirety by synthesis. In each case, proteolytic enzymes within the cell would apparently degrade the desired product, necessitating its production in conjugated form, i.e., in tandem with another protein which protected it by compartmentalization and which could be extracellulary cleaved away to yield the product intended. This work is described in the following Patent Specification Nos. 47889, 47891, 47890 and published * U.K. Patent Application No. 2 007 67OA. ( Escherichia).
While the synthetic gene approach has proven useful in the several cases thus far discussed, real difficulties arise in the case of far larger protein products, e.g., growth hormone and interferon, whose genes are correspondingly more complex and less susceptible to facile synthesis. At the same time, it would be desirable to express such products unaccompanied by conjugate protein, the necessity of whose expression requires diversion of resources within the organism better committed to construction of the intended product.
Other workers have attempted to express genes derived not by organic synthesis but rather by reverse transcription from the corresponding messenger RNA purified from tissue. Two problems have attended this approach. To begin with, reverse transcriptase may stop transcription from mRNA short of completing cDNA for the entire amino acid sequence desired. Thus, for example, Villa-Komaroff et al obtained cDNA for rat proinsulin which lacked codons for the first three amino acids of the insulin precursor. Proc. Nat'l. Acad. Sci,, PSA 75 3727 (1978). Again, reverse transcription of mRNA for polypeptides that are expressed in precursor form has yielded cDNA for the precursor form rather than the bioactive protein that results when, in a eukaryotic cell, leader sequences are enzymatically removed. Thus far, no bacterial cell has been shown to share that capability, so that mRNA transcripts have yielded expression products containing the leader sequences of the precursor form rather than the bioactive protein itself. Villa-Komaroff, supra (rat proinsulin); Ρ. H. Seeburg et al, Nature 276 , 795 (1978) (rat pregrowth hormone).
Finally, past attempts by others to bacterially express human hormones (or their precursors) from mRNA transcripts have on occasion led only to the production of conjugated proteins not apparently amenable to extra-cellular cleavage, e.g., Villa-Komaroff, supra, (penicillinase-proinsulin); Seeburg, supra (betalactamase-pregrowth hormone).
Human Growth Hormone Human growth hormone (HGH) is secreted in the human pituitary. It consists of 191 amino acids and with its molecular weight of about 21,500, is more than three times as large as insulin. Until the present invention, human growth hormone could be obtained only by laborious extraction from a limited source — the pituitary glands of human cadavers. The consequent scarcity of the substance has limited its applications to the treatment of hypopituitary dwarfism, and even here reliable estimates suggest that human-derived HGH is available in sufficient quantity to serve not more than about 50 % of afflicted subjects.
Xn summary, a need has existed for new methods of producing HGH and other polypeptide products in quantity, and that need has been particularly acute in the case of polypeptides too large to admit of organic synthesis or, for that matter, microbial egression from entirely synthetic genes. Expression of mammalian hormones from mRNA transcripts has offered the promise of sidestepping difficulties that attend the synthetic approach, but until the present has permitted only microbial production of bio-inactive conjugates from which the desired hormone could not practicably be cleaved.
The present invention provides an expression plasmid comprising functional genes for anpicillin and tetra25 cycline resistance and, lying between said genes, a tandem lac promoter system oriented to promote expression in the direction of the gene for tetracycline resistance.
S0462 plural restriction sites being positioned downstream from said promoter system which yield» respectively, cohesive and blunt ends upon cleavage, permitting proper insertion of heterologous DNA .between said sites so as to come under the control of eaid promoter system. Such a plasmid is, for example, plasmid pGH6.
The present invention also provides a viable culture of bacterial transformants comprising a plasmid of the invention.
The present invention also relates to methods and means for expressing quasi-synthetic genes wherein reverse transcription provides a substantial portion, preferably a majority, of the coding sequence without laborious resort to entirely synthetic construction, while synthesis of the remainder of the coding sequence affords a completed gene capable of expressing the desired polypeptide unaccompanied by bio-inactivating leader sequences or other extraneous protein.
Alternatively, the synthetic remainder may yield a proteolysis-resistant conjugate so engineered as to permit extra-cellular cleavage of extraneous protein, yielding the bioactive form. The invention accordingly makes available methods and means for microbial production of numerous materials hitherto produced only in limited quantity by costly extraction from tissue, and still others previously incapable of industrial manufacture. Xn its most pre5 ferred embodiment the invention represents the first occasion in which a medically significant polypeptide hormone (human growth hormone) has been bacterially expressed while avoiding both intracellular proteolysis and the necessity of compartmentalizing the bioactive form in extraneous protein pending extracellular cleavage. Microbial sources for human growth hormone made available by the invention offer, for the first time, ample supplies of the hormone fcr treatment of hypopituitary dwarfism, together with other applications here15 tofore beyond the capacity of tissue-derived hormone sources, including diffuse gastric bleeding, pseudarthrosis, burn therapy, wound healing, dystrophy and bone knitting.
The manner in which these and other objects and advantages of the invention may be obtained will appear more fully from the detailed description which follows, and from the accompanying drawiags relating to a preferred embodiment of the invention, in which: Figure 1 depicts the synthetic scheme for eonstruc25 tion of a gene fragment coding for the first 24 amino acids of human growth hormone, together with the start signal ATG and linkers used in cloning. The arrows in the coding or upper strand (0) and in the complementary or lower strand (L) indicate the oligonucleotides joined to form the depicted fragment; Figure 2 depicts joinder of the ϋ and *L oligonucleotides to form the gene fragment of Figure 1, and its insertion in a plasmid cloning vehicle; Figure 3 illustrates the DNA sequence (coding strand only) of the Hae III restriction enzyme fragment of a pituitary mRNA transcript, with the numbered amino acids of human growth hormone for which they code. Key 0 4 6 2 restriction sites are indicated, as is DNA (following stop) for untranslated mRNA; Figure 4 illustrates the construction of a cloning vehicle for a gene fragment coding for the amino acids of human growth hormone not synthetically derived, and the construction of that gene fragment as complementary DNA by reverse transcription from mRNA isolated from a human pituitary source; and Figure 5 illustrates the construction of a plasmid. 10 capable, in bacteria, of expressing human growth hormone, beginning with the plasmids of Figures 2 and 3.
The general approach of the invention involves the combination in a single cloning vehicle of plural gene fragments which in combination code for expression of the desired product. Of these, at least one is a cDNA fragment derived by reverse transcription from mRNA isolated from tissue, as by the method of A. Ullrich et al, Science 196 , 1313 (1977 ). The cDNA provides a substantial portion, and preferably at least a majority, of the codons for the desired product, while remaining portions of the gene are supplied synthetically. The synthetic and mRNA transcript fragments are cloned separately to provide ample quantities for use in the later combination step.
A variety of considerations influence distribution of codons for the end product as between synthetic and cDNA, most particularly the DNA sequence of complementary DNA determined as by the method of Maxam and Gilbert, Proc. Nat’l Acad. Sci. USA 74, 560 (1977). Complementary DNA obtained by reverse transcription will invariably contain codons for at least a carboxy terminal portion of the desired product, as well as other codons for untranslated mRNA downstream from the translation stop signal(s) adjacent the carboxy terminus. The presence of DNA for untranslated RNA is largely irrelevant, although unduly lengthy sequences of that kind may be removed, as by restriction enzyme cleavage, to conserve cellular resources employed in replicating and expressing the DNA for the intended product. In particular cases, the cDNA will contain codons for the entire amino acid sequence desired, as well as extraneous codons upstream from the amino terminus of the intended product. For example, many if not all polypeptide hormones are expressed in precursor form with leader or signal sequences of protein involved, e.g., in transport to the cellular membrane. In expression from eukaryotic cells, these sequences are enzymatically removed, such that the hormone enters the periplasmic space in its free, bioactive form. However, microbial cells cannot be relied upon to perform that function, and it is accordingly desirable to remove sequences coding for such signals or leader sequences from the mRNA transcript. In the course of that removal process the translation start signal is also lost, and almost invariably some codons for the intended product will be removed as well. The synthetic component of the quasi-synthetic gene product of the invention returns these latter codons, as well as supplying anew a translation start signal where the vehicle into which the hybrid gene will ultimately be deployed itself lacks a properly positioned start.
Elimination of the leader sequence from pregrowth hormone cDNA is advantaged by the availability of a restriction site within the growth hormone-encoding portion of the gene. The invention may nevertheless be practiced without regard to the availability of such a site, or in any event without regard to the availability of a restriction site sufficiently near the amino terminus of the desired polypeptide as to obviate the need for extensive synthesis of the gene component not derived from mRNA. Thus, in any cDNA coding for the desired polypeptide and a leader or other bioinactivating sequence the boundary between the latter's codons and thoee of the mature polypeptide will appear from the aaino acid sequence of the mature polypeptide. One may simply digest into the gene coding of the peptide of choice, removing the unwanted leader or other sequence. Thus, for example, given cDNA sueh as: TTAAGCCCTGATCGT ... etc.
AATTCGGGACTAGCA ... where the endpoint of digestion is indicated by arrow, reaction conditions for exonuelease digestion may be chosen to remove the upper sequences a and b, whereafter 51 nuclease digestion will automatically eliminate the lower sequences *c and d. Alternatively and more precisely, one may employ DNA polymerase digestion in the presence of deoxynucleotide triphosphates {Bd(A,T,C,G)TP). Thus, in the foregoing example, DNA polymerase in the presence of dGTP will remove sequence °cn (then stop at 6), SI nuclease will then digest a; DNA polymerase in the presence of dTTP will remove d, (then stop at T) and SI nuclease will then excise b, and so on. See generally A. Kornberg, DNA Synthesis, pp. 87-88, W. H. Freeman and Co., San Francisco (1974).
More preferably, one may simply construct a restriction site at a convenient point within the portion of the cDNA coding for the desired product, by an application of the mismatch repair synthesis technique of A. Razin et al, Proc. Nat'l Acad. Sci. OSA 75, 4268 (1978). By this technique one or more bases may be substituted in an existing SNA sequence, using primers containing the mismatched substituent. At least seven palindromic 4-base pair sequences are uniquely recognized by known restriction enzymes, i.e., AGCT (AIu 1), CCGG (Hpa II), CGCG (Tha I', GATC (Sau 3A',,GCGC (Hha', GGCC (Hae III' and TCGA (Tag I). Where the cDNA sequence contains a sequence differing from one such site in a single base, as statistically is highly likely, repair synthesis will yield replicate cDNA containing the proper, substituent base and hence the desired restriction site. Cleavage will delete DNA for the unwanted leader, after which synthesis will replace codons required for expression of the complete polypeptide. E.g.,: -leader codons for desired product a· CDNA CAGG r mismatch repair synthesis codons for desired —productquasisynthetic DNA It will be appreciated, of course, that longer restriction sites may be likewise inserted where desired, or that successive repairs may create 4-base pair restriction sites where only two bases common to the site appear at the desired point, etc.
Applications will appear in which it is desirable to express not only the amino acid sequence of the intended product, but also a measure of extraneous but specifically engineered protein. Pour such applications may be mentioned by way of example. First, the guasi20 synthetic gene may represent a hapten or other immunological determinant upon which immunogenicity is conferred by conjugation to additional protein, such that vaccines are produced. See generally, Patent Specification No. 47890. Again, it may be desirable for biosafety reasons to express tbe intended product as a conjugate with other, bio-inactivating protein ao designed as to permit extracellular cleavage to yield the active form. Third, applications will be presented in which transport signal polypeptides will precede the desired product, to permit production of the same by excretion through the cell membrane, so long as the signal peptide can then be cleaved,. Finally, extraneous conjugate designed to permit specific cleavage extracellularly may be employed to compartmentalise intended products otherwise susceptible to degradation by proteases endogenous to the microbial host. At least in the latter three applications, the synthetic adapter molecular employed to complete the coding sequence of the mRNA transcript can additionally incorporate codons for amino acid sequences specifically cleavable, as by enzymatic action. For example, trypsin will cleave specifically at arg-arg or lys-lys, etc. See Patent Specification No. 47890, supra.
From the foregoing, it will be seen that in its broadest aspect the invention admits of manifold applications, each having in common these attributes: — a mRNA transcript is employed which codes for a substantial portion of the intended polypeptide's amino acid sequence but which, if expressed alone, would produce a different polypeptide either smaller or larger than the intended product; — protein-encoding codons for amino acid sequences other than those contained in the intended product, if any, are removed; -- organic synthesis yields fragment(s) coding for the remainder of the desired sequence; and -- the mRNA transcript and synthetic fragment(s) are combined and disposed in a promoter containing cloning vehicle for replication and expression of either the intended product absent extraneous conjugated protein, or intended product conjugated to but specifically cleavable from extraneous protein.
Of course, the expression product will in every case commence with the amino acid coded for by the translation start signal (in the case of ATG, f-methionine). One can expect this to be removed inttacellularly, or in any event to leave the bioactivity of the ultimate product essentially unaffected.
Although it provides a method of general applicability in the production of useful proteins, including antibodies and enzymes, the invention is particularly suited to the expression of mammalian polypeptide hormones and other substances having medical applications, e.g., glucagon, gastrointestinal inhibitory polypeptide, pancreatic polypeptide, adrenocorticotropin, beta-endorphins, interferon, urokinase, blood clotting factors and human albumin. A preferred embodiment illustrative of the invention is next discussed, in which a guasi-synthetic gene coding for human growth hormone is constructed, cloned and microbially expressed. (Percentages are calculated by weight1 Construction and Expression of a Cloning Vehicle for Human Growth Hormone 1, Cloning the Hae III fragment of the mRNA transcript (Figs. 3 and 4) Polyadenylated mRNA for human growth hormone (HGH) was prepared from pituitary growth hormone-producing tumors by the procedure of A. Dllrich et al. Science 196, 1313 (1977) 1.5/«.g of double strand (ds) cDNA was prepared from 5 /F3 of this RNA essentially as described by Wickens et al. J. Biol Chem. 253 2483 (1978), except that RNA polymerase Klenow fragment, H. Klenow, Proc. Nat'l. Aci. PSA. 65, 168 (1970), was substituted for DNA Polymerase I in the second strand synthesis. The 0462 restriction .pattern of BGH is such that Bae XII restriction sites are present in the 3’ noncoding region and in the sequence coding for amino acids 23 and 24 of BGH, as shown in Fig. 3. Treatment of ds BGH cDNA with Bae III gives a SNA fragment of 551 base pairs ("bp) coding for amino acids 24-191 of HGH. Thus, 90 ng of the cDNA was treated with Bae III, electrophoresed on an 84 polyacryclaraide gel, and the region at 550 bp eluted. Approximately 1 ng of cDNA was obtained. pBR322 prepared as in F. Bolivar et al., Gene 2 (1977) 95-113 was chosen as the cloning vehicle for the cDNA. pBR322 has been fully characterized, J.G. Sutcliffe, Cold Spring Harbor Symposium 43, 70 (1978) is a multicopy replicating plasmid which exhibits both ampicillin and tetracycline resistance owing to its inclusion ef the corresponding genes (ApR and aTcRn, respectively, in Fig. 4), and which contains recognition sites for the restriction enzymes Pst I, EcoRI and Hind III as shown in the Figure.
Cleavage products of both Bae III and Pst I are blunt ended. The GC tailing method of Chang. A.C.Y. et al. Nature 275 617 (1978) could accordingly be employed to combine the blunt-ended products of Pst I cleavage of pBR322 and of Bae III digestion of the mRNA transcript, inserting the cDNA fragment into the Pst I site of pBR322 in such manner as to restore the Bae III restriction sites (GGiCC) on the cDNA while restoring the Pst I restriction sites (CTGCA4G) at each end of the insert.
Thus, terminal deoxynucleotidyl transferase (TdT) was used to add approximately 20 dC residues per 3' terminus as described previously, Chang, A.Y.C., supra. 60 ng of Pst I-treated pBR322 was tailed similarly with about 10 dG residues per 3' terminus. Annealing of the dC-tailed ds cDNA with the dG-tailed vector DNA was performed in 130 ul of lOmM Tris-BCl (pH 7.5), 100 mM NaCl, 0.25 mM EDTA. The mixture was heated to 70°C, allowed to cool slowly to 37®C (12 hours), then to 20°C (6 hours) before being used to transform £. coll. xl776. DNA sequence analysis of the plasmid pHGH31 cloned in xl776 by the method of Maxam and Gilbert, Proc, Nat'l. Acad.Sci. PSA 74, 560 (1977) resulted in confirmation of the codons for amino acids 24-191 of HGH, as shown in Figure 3.
E, Coll K-12 strain xl776 has the genotype F" Jtgnft5 3 dapD8 mlnAl supE42 Δ.40 [gal-uvrB] λ" minB2 rfb-2 nalA25 oms-2 thyA57* metC65 oms-1 A29IbioH-asd] cycB2 cycAl hsdR2. X1776 has been certified by the National Institutes of Health as an EK2 host vector system. xl776 has an obligate requirement for diaminopimelic acid (DAP) and cannot synthesize the mucopoly15 saccharide colanic acid. It thus undergoes DAP-less death in all environments where DAP is limiting but sufficient nutrients exist to support cellular metabolism and growth. It requires thymine or thymidine and undergoes thymineless death with degradation of DNA when thymine and thymidine are absent from the environment even when sufficient nutrients are present to sustain metabolic activity. xl776 is extremely sensitive to bile and thus is unable to survive passage through the intestinal tract of rats. xl776 is extremely sensitive to detergents, antibiotics, drugs and chemicals. xl776 is unable to carry out either dark or photo repair of DV-induced damage and is thus several orders of magnitude more sensitive to sunlight than wild-type strains of E. coli. xl776 is resistant to many transducing phages and is conjugation deficient for inheritance of many different types of conjugative plasmids due to the presence of various mutations. xl776 is resistant to nalidixic acid, cycloserine and trimethoprim. These drugs can therefore be added to media to permit monitoring of the strain and to preclude transformation of contaminants during transformation. s Ο 4 6 2 211776 grows with a generation time of about JD min. in either L broth or Penassay broth when supplemented with 100 /ig DAP/ml and 4thymidine/ml and reaches final densities of 8-10 x 10® eells/al at stationary phase. Gentle agitation by swirling and shaking back and forth for a period of 1-2 min. adequately suspends cells with maintenance of 100% viability. Additional details concerning x!776 appear in R. Curtis et al., Molecular Cloning of Recombinant DNA, 99-177, Scott and Werner, eds., Academic Press (N.Y.1977). xl776 has been deposited in the American Type Culture Collection (July 3, 1979: ATCC accession no. 31537, without restriction. 2. Construction and Cloning of the Synthetic Gene Fragment (Figs. 1 and 2) The strategy for construction of the HGH quasisynthetic gene included construction of a synthetic fragment comprising a blunt-end restriction cleavage site adjacent the point at which the fragment would be joined to the mRNA transcript. Thus, as shown in Pig. 1, the synthetic gene for the first 24 amino acids of HGH contained a Hae III cleavage site following amino acid 23. The distal end of the synthetic fragment was provided with a linker that permitted annealing to a single strand terminal resulting from restriction cleavage in the plasmid in which the mRNA transcript and synthetic fragment would ultmately be joined.
As shown in Fig. 1, the 5' ends of the duplex fragment have single stranded cohesive termini for the Eco RI and Hind III restriction endonucleases to facili30 tate plasmid construction. The methionine codon at the left end provides a site for initiation of translation. Twelve different oligonucleotides, varying in size from undecamer to hexadecaner, were synthesized by the improved phosphotriester method of Crea, R. Proc, Nat'l. Acad. Sci. OSA 75, 5765 (1978). These oligonucleotides, Οχ to Ug and Lj to Lg, are indicated by arrows. /^g amounts of O2 through Og and I»2 through Lg were phosphorylated using T4 polynucleotide kinase and (-$32-P)ATP by a published procedure. Goeddel, D. V. et al. Proc. Nat’l. Acad. Sci. OSA 76, 106 (1979).
Three separate T4 ligase catalyzed reactions were performed: 10 f-g of 5'-OH fragment Οχ was combined with the phosphorylated O2, 1*5 and Lg; phosphorylated O3, 04, L3 and 1.4 were combined; and 10 Λ9 of 5’-OH fragment Iq was combined with the phosphorylated L2, 05 and Og. These ligations were carried out at 4’C for 6 hours in 300/·! of 20 mM Tris-HCl (pH 7.5), mM MgCl2, 10 mM dithiothreitol, 0.5 mM ATP using 100 units of T4 ligase. The three ligation mixtures were then combined, 100 units T4 ligase added, and the reaction allowed to proceed for 12 hours at 20’C. The mixture was ethanol precipitated and electrophoresed on a 10% polyacrylamide gel. The band migrating at 84 base pairs was sliced from the gel and eluted. pBR322 (l/xg) was treated with Eco RI and Hind III, the large fragment isolated by gel electrophoresis and ligated to the synthetic DNA. This mixture was used to transform E. coli. K-12 strain 294 (end A, thi~, hsr", hsnifc·*·). Strain 294 was deposited October 30, 1978 in the American Type Culture Collection (ATCC No. 31446), without restriction, sequence analysis by the Maxam and Gilbert technique, supra, on the Eco ri - Hind III insert from a plasmid pHGH3 of one transformant confirmed the sequence depicted in Figure 1. 3. Construction of Plasmid for the Bacterial Expression of HGH (Fig. 5) With the synthetic fragment in pHGH3 and the mRNA transcript in pHGH31, a replicable plasmid containing both fragments was constructed using the expression plasmid pGH6, as shown in Fig. 5. The expression plasmid, which contains tandem lac promoters, was first constructed as follows. Ά 285 base pair geo SI fragment containing two §5 base pair OV5 lae promoter fragments separated by a 95 base pair heterlegous SMA fregent was isolated from plasmid pK8268, K. Saekaan, et al., Cell, Vol. 13, 55-71 (1978). The 285 bp fragment was inserted into the geo RX site ©f pBR322 and a clone pGHl isolated with tbe promoters oriented toward and in proper reading phase with the gene for tetracycline resistance. The Eco RX site distal to the latter gene was destroyed by partial Eco RX digestion, repair of the resulting single stranded Eco RX ends with DBA polymerase X and recircularisation of the plasmid by blunt-end ligation. The resulting plasmid, pGH€, contains a single Eco RX site properly positioned with respect to the promoter system into which the completed gene for BGH could be inserted.
To ready the synthetic fragment for combination with the RNA transcript, lOjug of pBGH3 was cleaved with Eco RX and Hae XIX restriction endonucleases and the 77 base pair fragment containing coding sequences for BGH amino acids 1=23 was isolated from an 8% polyacrylamide gel.
The plasmid pBGH 31 ( S/ag) was next cleaved with Bae XIX. The 551 bp BGH seguence and a comigrating 540 bp Bae XXX fragment of pBR322 were purified by gel electrophoresis. Subsequent treatment with Xma I cleaved only the HGH seguence, removing 39 base pairs from the 3' noncoding region. The resulting 512 bp fragment was separated from the 540 bp pBR322 Bae III piece by electrophoresis en a 6% polyacrylamide gel. 0.3 Ag of the 77 bp Bco RI - Bae XIX fragment was polymerised with T4 ligase in a 16 /il reaction vessel fcr 14 hours at 4°C. The mixture was heated to 70° C for 5' to inactivete the ligase, then treated with Eco RI (to cleave fragments which had dimerized through their Eco RI sites) and with Sma X (to cleave Xma I dimers), yielding a 591 bp fragment with an Eco RI cohesive* end and a Sma I blunt end. After purification on a 6% polyacrylamide gel, approximately 30 ng of thi* fragment were obtained. It should be noted that the expression plasmid pGH6 contains no Xma I recognition site. However, Sma I recognizes the same site as Xma I, but cuts through the middle of it, yielding blunt ends. The Sma-cleaved terminus of the fragment derived from gHGH 31 can accordingly be blunt end ligated into pGH6.
The expression plasmid pGB6, containing tandem lac DV5 promoters, was treated successively with Bind III, nuclease SI, and Eco RI and purified by gel electrophoresis. 50 ng of the resulting vector, which had one Eco RI cohesive end and one blunt end was ligated to 10 ng of the 591 bp BGB DNA. The ligation mixture was used to transform E. feoli. X1776. Colonies were selected for growth on tetracycline (12.5>fcg/»l). It is noteworthy that insertion of the hybrid BGH gene into pGH6 destroys the promoter for the tetracycline resistance gene, but that the tandem lac promoter permits readthrough of the structural gene for tet resistance, retaining this selection characteristic. Approximately 400 transformants were obtained. Filter hybridization by the Grunstein - Hogness procedure, Proc. Nat'l. Acad. Sci. PSA, 72, 3961 (1975) identified 12 colonies containing BGH sequences. The plasmids isolated from three of these colonies gave the expected restriction patterns when cleaved with Bae III, Pvu II, and Pst I. The DNA sequence of one clone, pBGH107, was determined.
Human growth hormone expressed by the transformants was easily detected by direct radioimmunoassay performed on serial dilutions of lysed cell supernatants using the Phadebas BGH PRIST kit (Farmacia).
To demonstrate that BGH expression is under the control of the lac promoter, pGHG 107 was transformed into E. toll strain D1210 a lac+(iQo+zty+), a lac repressor overproducer. Meaningful levels of HGH expression could not be detected until addition of the inducer IPTG (isopropylthiogalactoside).
Removal of the Eco RI site in pGH107 would leave the ATG start signal the same distance from the ribosome binding site codons of the lac promoter as occurs in nature between those codons and the start signal for ^-galactosidease. To determine whether expression would be increased by mimicki.ng this .-natural spacing we converted pGH107 to pGB107-l by opening the former with Eco RI, digesting the resulting single strand ends with SI endonuclease, and recircularizing by blunt-end ligation with T4 ligase. Although the resulting plasmid proved likewise capable of expressing HGH, it surprisingly did so fo a lesser extent than did pGH107, as shown by direct radioimmunoassay.
It will be apparent to those skilled in the art that the present invention is not limited to the preferred embodiment just discussed, but rather only to the lawful scope of the appended claims. Variations other than those hitherto discussed will be apparent, whether in the choice of promoter system, parental plasmid, intended polypeptide product or elsewhere. For example, other promoter systems applicable to the present invention include the lambda promoter, the arabinose operon (phi 80 d ara) or the colicine El, galactose, alkaline phosphatase or tryptophan promoter systems. Host organisms for bacterial expression may be chosen, e.g., from among the Enterobacteriaceae, such as strains of Escherichia coli and Salmonella; Bacillaceae, such as Bacillus subtil is; Pneumococcus; Streptococcus; and Haemophilus influenzae. Of course, the choice of organism will control the levels of physical containment in cloning and expression that should be practiced to comply with National Institutes of Health Guidelines for Recombinant DNA, 43 Fed. Reg. 60,080 (1978).
While preferred for bench-scale practice of the present invention, E. coli. xl775 could prove of limited practicality in large-scale industrial manufacture owing. to the debilitations purposefully incorporated in it for biosafety reasons. With appropriate levels of physical, rather than biological, containment such organisms as E. toll. K-12 strain 294, supra, and E. coli. strain RRI, genotype» Pro~Leu~Thi’Rg-reeA+strr lac ycould be employed in larger acale operation. E. coli. RRI is derived from E. coli HB101 (B.W. Boyer, et al, J· Mol.Bio, (1969) 41 459-472) by mating with E. toll.K12 strain KX.16 as the Bfr donor. See J.B. Miller, Experiments in Molecular Genetics (Cold Spring Barbor, New Yor, 1972). A culture of E. coll. RRI was deposited October 30, 1978 with the American Type Culture Collection, without restriction as to access (ATCC No. 31343).
A culture of xl776 was similarly deposited July 3, 1979 in the American Type Culture Collection (ATCC No. 31537). Deposits of the following were made in the American Type Culture Collection July 3, 1979: plasmid pHGH107 (ATCC No. 40011)? plasmid pGB6 (ATCC No. 40012)? strain xl776 transformed with pBGH 107 (ATCC No. 31538) and E. coli K12 strain 294 transformed with pGH6 (ATCC No. 31539).
Organisms produced according to the invention may be employed in industrial acale fermentative production of human growth hormone, yielding product in quantities and for applications hitherto unattainable. For example, transformant E. coli cultures may be grown up in aqueous media in a steel or other fermentation vessel conventionally aerated and agitated, in aqueous media at, e.g., about 37*C and near neutral pH (e.g., pB 7+ 0.3 supplied with appropriate nutriments such as carbohydrate or glycerol, nitrogen sources such as ammonium sulfate, potassium sources such as potassium phosphate, trace elements and magnesium sulfate.
Transformant organisms preferably exhibit one or more selection characteristics, such as antibiotic resistance, so that eelection pressures may be imposed to discourage competitive growth of wild-type 5. coli. As an example, in the case of an ampicillin or tetracycline-resistant organism the antibiotic may be added to the fermentation medium to select out wild-type organisms which lack the resistance characteristic.
Upon completion of fermentation the bacterial suspension is centrifuged or the cellular solids otherwise collected from the broth, and then lysed by physical or chemical raeans. Cellular debris is removed from super10 natant and soluble growth hormone isolated and purified.
Human growth hormone may be purified from bacterial extracts using one or a combination of (1) polyethyleneimine fractionation; (2) gel filtration chromatography on Sephacryl S-200; (3) ion exchange chromatography on Bic-rex-70 resin or CM Sephadex; (4) ammonium sulphate and/or pH fractionation; and (5) affinity chromatography using antibody resins prepared from anti-HGH IgG isolated from immunosensitized animals or hybridomas; and desorbed under acid or slightly denaturing conditions. (Sephadex, Sephacryl and Bio-rex are Trade Marks.) Patent Specification No. describes and claims a method of constructing a replicable cloning vehicle capable, in a microbial organism, of expressing a particular polypeptide of known amino acid sequence wherein a gene coding for the polypeptide is inserted into a cloning vehicle and placed under the control of an expression promoter, which comprises a) obtaining by reverse transcription from messenger RNA a first gene fragment for an expression product other than said polypeptide, which fragment comprises at least a portion of the coding sequence for said polypeptide; b) where the first fragment comprises proteinencoding codons for amino acid sequences other than those contained in said polypeptide, eliminating the same while retaining at least a portion of said coding sequence, the resulting fragment nevertheless coding for an expression product other than said polypeptide; the product of step (a) or, where required, step (b) being a fragment encoding less than all of the amino acid sequence of said polypeptide; c) providing by organic synthesis one or more gene fragments encoding the remainder of the amino acid sequence of said polypeptide, at least one of said fragments coding for the amino-terminal portion of the polypeptide; and d) deploying the synthetic gene fragment(s) of step (c) and that produced in step (a) or (b>, as the case may be, in a replicable cloning vehicle in proper reading phase relative to one another and under the control of an expression promoter; whereby a replicable cloning vehicle capable of expressing 15 the amino acid sequence of said polypeptide is formed.
Companion Divisional Patent Specification No. 504if describes and claims an expression plasmid comprising functional genes for anpicillin and tetracycline resistance and, lying between said genes, a randem lac promoter system oriented to promote expression in the direction of the gene for tetracycline resistance, plural restriction sites being positioned downstream from said promoter system which yield, respectively, cohesive and blunt ends upon cleavage, permitting proper insertion of heterologous DMA between said sites so as to come under the control of said promoter system.
Claims (13)
1. CLAIMS:1. A replicable bacterial plasmid capable, in a transformant bacterium, of expressing human growth hormone unaccompanied by extraneous conjugated protein. 5
2. A plasmid according to claim 1 whose human growth hormone-encoding gene comprises in substantial proportion cDNA or a replication thereof.
3. A plasmid according to claim 1 or claim 2 which exhibits resistance to at least one antibiotic. 10
4. A plasmid according to claim 3 which lacks the tet promoter yet exhibits tetracycline resistance.
5. A plasmid according to any one of claims 1 to 4 in which the human growth hormone-encoding gene is under the control of tandem lac promoters. 15
6. The plasmid pHGH107.
7. The plasmid pHGH107-l.
8. A plasmid according to claim 1 capable, in transformant Escherichia coli bacteria, of expressing the amino acid sequence successively depicted in Figures 20 1 and 3.
9. A viable culture of bacterial transformants comprising plasmids according to any one of claims 1 to 8.
10. A method of producing human growth hormone which 25 comprises: (a) disposing a culture according to claim 9, within a fermenter vessel comprising aeration and agitation means in an aqueous, nutriment-containing fermentation broth: (b) growing up the culture under aeration and agitation while supplying additional nutriments as required to maintain vigorous growth. (c) separating the resulting cellular mass from the fermentation broth; (d) lysing the cells to free the contents thereof; (e) separating cellular debris from supernatant; and (f) isolating and purifying human growth hormone contained in the supernatant.
11. A method according to claim 10, wherein the bacteria are transformant Escherichi coli having a selection characteristic and wherein selection pressure is applied to discourage competition by wild-type Escherichia coli.
12. A plasmid as claimed in claim 1 which includes two or more of the features specified in claims 2-5 or 11.
13. A method as claimed in claim 10 or 11 substantially as hereinbefore described.
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IE1214/80A IE50460B1 (en) | 1979-07-05 | 1980-06-12 | Microbial expression of quasi-synthetic genes |
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IE2194/84A IE50462B1 (en) | 1979-07-05 | 1980-06-12 | Bacterial plasmid encoding human growth hormone |
IE2193/84A IE50461B1 (en) | 1979-07-05 | 1980-06-12 | Plasmid with tandem promoter system |
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- 1980-07-02 PT PT71487A patent/PT71487A/en unknown
- 1980-07-02 EG EG80392A patent/EG14819A/en active
- 1980-07-02 GR GR62345A patent/GR69320B/el unknown
- 1980-07-03 BR BR8008736A patent/BR8008736A/en unknown
- 1980-07-03 WO PCT/US1980/000838 patent/WO1981000114A1/en unknown
- 1980-07-03 PH PH24236A patent/PH19814A/en unknown
- 1980-07-03 GB GB08234691A patent/GB2121047B/en not_active Expired
- 1980-07-03 GB GB8021860A patent/GB2055382B/en not_active Expired
- 1980-07-04 DD DD80222413A patent/DD157343A5/en unknown
- 1980-07-04 CS CS804809A patent/CS250652B2/en unknown
- 1980-07-04 AR AR80281658A patent/AR244341A1/en active
- 1980-07-04 ES ES493149A patent/ES493149A0/en active Granted
- 1980-07-04 KR KR1019800002658A patent/KR830003574A/en unknown
- 1980-07-04 DD DD80244147A patent/DD210070A5/en unknown
- 1980-07-04 DD DD80244149A patent/DD210071A5/en unknown
- 1980-07-04 JP JP55092161A patent/JPH0612996B2/en not_active Expired - Lifetime
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1981
- 1981-02-02 ES ES499043A patent/ES8205265A1/en not_active Expired
- 1981-02-20 NO NO81810608A patent/NO167673C/en unknown
- 1981-03-04 DK DK198100973A patent/DK173503B1/en not_active IP Right Cessation
- 1981-03-05 RO RO103596A patent/RO93374B/en unknown
- 1981-08-26 US US06/296,099 patent/US4634677A/en not_active Expired - Lifetime
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1982
- 1982-03-09 US US06/356,564 patent/US4601980A/en not_active Expired - Lifetime
- 1982-03-09 US US06/361,160 patent/US4604359A/en not_active Expired - Lifetime
- 1982-05-12 CS CS823457A patent/CS250655B2/en unknown
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1983
- 1983-01-17 FR FR8300612A patent/FR2518572B1/en not_active Expired
- 1983-04-25 CA CA000426675A patent/CA1202256A/en not_active Expired
- 1983-06-01 YU YU01212/83A patent/YU121283A/en unknown
- 1983-06-01 YU YU01211/83A patent/YU121183A/en unknown
- 1983-08-14 IL IL69492A patent/IL69492A0/en unknown
- 1983-08-24 AU AU18388/83A patent/AU1838883A/en not_active Abandoned
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1984
- 1984-04-09 CS CS842708A patent/CS254973B2/en unknown
- 1984-08-13 SG SG569/84A patent/SG56984G/en unknown
- 1984-09-13 KE KE3451A patent/KE3451A/en unknown
- 1984-09-13 KE KE3450A patent/KE3450A/en unknown
- 1984-09-13 KE KE3446A patent/KE3446A/en unknown
- 1984-09-25 US US06/654,340 patent/US4658021A/en not_active Expired - Lifetime
- 1984-11-08 HK HK873/84A patent/HK87384A/en not_active IP Right Cessation
- 1984-11-08 HK HK875/84A patent/HK87584A/en not_active IP Right Cessation
- 1984-11-08 HK HK874/84A patent/HK87484A/en not_active IP Right Cessation
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1985
- 1985-01-16 FI FI850198A patent/FI850198A0/en not_active Application Discontinuation
- 1985-12-30 MY MY764/85A patent/MY8500764A/en unknown
- 1985-12-30 MY MY765/85A patent/MY8500765A/en unknown
- 1985-12-30 MY MY763/85A patent/MY8500763A/en unknown
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1986
- 1986-02-24 NO NO86860680A patent/NO167674C/en unknown
- 1986-11-12 KR KR1019860009542A patent/KR870000701B1/en not_active IP Right Cessation
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1989
- 1989-04-18 JP JP1099888A patent/JPH0648987B2/en not_active Expired - Lifetime
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1990
- 1990-10-18 DK DK251490A patent/DK172132B1/en not_active IP Right Cessation
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1992
- 1992-09-25 JP JP4256344A patent/JP2622479B2/en not_active Expired - Lifetime
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1993
- 1993-06-29 NL NL930114C patent/NL930114I2/en unknown
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1994
- 1994-05-27 US US08/250,639 patent/US5424199A/en not_active Expired - Fee Related
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1995
- 1995-06-01 US US08/457,282 patent/US5795745A/en not_active Expired - Fee Related
- 1995-11-29 JP JP7310696A patent/JPH08242881A/en active Pending
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